Effects of interaction of hydrogen sulfide and nitric oxide on postharvestquality and antioxidant system of banana

  • CUI Wenyu ,
  • XU Xinyue ,
  • ZHANG Rentang ,
  • GONG Zhiqing ,
  • WANG Wenliang ,
  • WANG Yansheng
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  • 1(Institute of Agro-Products processing Science and Technology; Key Laboratory of Agro-Products Processing Technology of Shandong Province,SAAS,Shandong;Key Laboratory of Novel Food Resources Processing, Ministry of Agriculture,SAAS,Jinan 250100,China)
    2(College of food Science and Engineering, Shandong Agricultural University, Tai’an 271000,China)

Received date: 2020-02-11

  Online published: 2020-08-04

Abstract

As important signaling molecules, hydrogen sulfide (H2S) and nitric oxide (NO) form a complex plant signal network with other signal molecules. In order to further explore the effects of H2S, NO and their interactions on banana's quality and antioxidant system in low temperature storage, bananas were stored at 7 ℃ for 15 d after treatment with 1 mmol/L H2S, 2 mmol/L NO, 0.03 mmol/L c-PTIO (NO inhibitor) and distilled water. The results show that H2S can significantly increase the NO content. Both H2S and NO treatments can maintain the hardness of banana fruits, inhibit the increase of malondialdehyde (MDA) content and relative conductivity, reduce the chilling injury index, and maintain good gloss and smoothness of banana peel Bright colors. The effect of NO and H2S treatment is better than that of distilled water and c-PTIO treatment. Both NO and H2S treatment can increase the superoxide dismutase (SOD), catalase (CAT), peroxidase (POD), and ascorbic acid levels in banana fruits, as well as antioxidant enzyme activities such as oxidase (APX) and phenylalanine ammonia lyase (PAL), thereby reduces tissue oxidation levels and inhibiting membrane lipid oxidation processes. Among them, the effects of NO and H2S treatment were significant in the pre-storage period, while the effect of c-PTIO treatment was the worst. It can be seen that the interaction of H2S and NO plays an important role in inducing cold tolerance in bananas.

Cite this article

CUI Wenyu , XU Xinyue , ZHANG Rentang , GONG Zhiqing , WANG Wenliang , WANG Yansheng . Effects of interaction of hydrogen sulfide and nitric oxide on postharvestquality and antioxidant system of banana[J]. Food and Fermentation Industries, 2020 , 46(13) : 166 -173 . DOI: 10.13995/j.cnki.11-1802/ts.023598

References

[1] 罗自生,杜瑞雪,王延圣,等.硫氢化钠诱导采后香蕉耐冷性的研究[J].现代食品科技,2015,31(2):205-210.
[2] ZHANG T, CHE F, ZHANG H, et al. Effect of nitric oxide treatment on chilling injury, antioxidant enzymes and expression of the Cm CBF1 and Cm CBF3 genes in cold-stored Hami melon (Cucumis melo L.) fruit[J]. Postharvest Biology and Technology, 2017, 127: 88-98.
[3] FOYER C H, NOCTOR G. Oxidant and antioxidant signalling in plants a re-evaluation of the concept of oxidative stress in a physiological context [J]. Plant, Cell and Environment, 2005, 28(8): 1 056-1 071.
[4] FOYER C H, NOCTOR G. Ascorbate and glutathione: the heart of the redox hub [J]. Plant Physiology, 2011, 155(1): 2-18.
[5] WILSON L G, BRESSAN R A, FILNER P, et al. Light-dependent emission of hydrogen sulfide from plants[J]. Plant Physiology, 1978, 61(2):184-189.
[6] CARLOS GARCÃ-MATA, LAMATTINA L, HYDROGEN SULPHIDE. Hydrogen sulphide, a novel gasotransmitter involved in guard cell signalling[J]. New Phytologist, 2010, 188(4):977-984.
[7] SCUFFI D, ALVAREZ C, LASPINA N, et al. Hydrogen sulfide generated by L-cysteine desulfhydrase acts upstream of nitric oxide to modulate abscisic acid-dependent stomatal closure[J]. Plant Physiology, 2014, 166(4):2 065-2 076.
[8] SAMI F, FAIZAN M, FARAZ A, et al. Nitric oxide-mediated integrative alterations in plant metabolism to confer abiotic stress tolerance, NO crosstalk with phytohormones and NO-mediated post translational modifications in modulating diverse plant stress[J]. Nitric Oxide, 2018, 73:22-38.
[9] 郭芹, 吴斌,王吉德,等.NO处理对番木瓜采后贮藏性的影响[J]. 食品科学, 2011,32(4):227-231.
[10] ZHANG X, SHEN L, LI F, et al. Methyl salicylate-induced arginine catabolism is associated with up-regulation of polyamine and nitric oxide levels and improves chilling tolerance in cherry tomato fruit[J]. Journal of Agricultural and Food Chemistry, 2011, 59(17):9 351-9 357.
[11] YAMASAKI H, COHEN M F. Biological consilience of hydrogen sulfide and nitric oxide in plants: Gases of primordial earth linking plant, microbial and animal physiologies[J]. Nitric Oxide-Biology and Chemistry, 2016:55-56; 91-100.
[12] WANG Y Q, LI L, CUI W T, et al. Hydrogen sulfide enhances alfalfa (Medicago sativa) tolerance against salinity during seed germination by nitric oxide pathway[J]. Plant and Soil, 2012,351(1-2):107-119.
[13] LISJAK M, SRIVASTAVA N, TEKLIC T, et al. A novel hydrogen sulfide donor causes stomatal opening and reduces nitric oxide accumulation[J]. Plant Physiology and Biochemistry, 2010, 48(12): 931-935.
[14] HANCOCK J T, WHITEMAN M, et al. Hydrogen sulfide and cell signaling: Team player or referee?[J]. Plant Physiology and Biochemistry, 2014, 78:37-42.
[15] 周万海,师尚礼,寇江涛,等.一氧化氮对NaCl胁迫下苜蓿种子萌发的影响[J]. 核农学报,2012,26(4):710-716.
[16] PONGPRASERT N, SEKOZAWA Y, SUGAYA S, et al. A novel postharvest UV-C treatment to reduce chilling injury (membrane damage, browning and chlorophyll degradation) in banana peel[J]. Scientia Horticulturae, 2011, 130(1):73-77.
[17] EUM H L, HWANG D K, LEE S K, et al. Nitric oxide reduced chlorophyll degradation in broccoli (Brassica oleracea L. var. italica) florets during senescence[J]. Food Science and Technology International, 2009, 15(3):223-228.
[18] 陈发河,张美姿,吴光斌.NO处理延缓采后枇杷果实木质化劣变及其能量代谢的关系[J]. 中国农业科学,2014,47(2):2 425-2 434.
[19] 范蓓,杨杨,王锋,等.外源NO处理对采后芒果耐冷性的影响[J]. 核农学报,2013,27(6):800-804.
[20] XU M, DONG J, ZHANG M, et al. Cold-induced endogenous nitric oxide generation plays a role in chilling tolerance of loquat fruit during postharvest storage[J]. Postharvest Biology & Technology, 2011, 65:5-12.
[21] 王倩.H2S延长梨果实及甘薯块根采后贮藏期的抗氧化机制研究[D].合肥:合肥工业大学,2012.
[22] GARCIÍ-LIMONES C, HERVÁS A, NAVAS-CORTÉS J A, et al. Induction of an antioxidant enzyme system and other oxidative stress markers associated with compatible and incompatible interactions between chickpea (Cicer arietinum L.) and Fusarium oxysporum f. sp.ciceris[J]. Physiological and Molecular Plant Pathology, 2002, 61(6):325-337.
[23] FU P, WANG W, HOU L, et al. Hydrogen sulfide is involved in the chilling stress response in Vitis vinifera L.[J]. Acta Societatis Botanicorum Poloniae, 2013, 82(4):295-302.
[24] YINGSANGA P, SRILAONG V, KANLAYANARAT S, et al. Relationship between browning and related enzymes (PAL, PPO and POD) in rambutan fruit (Nephelium lappaceum Linn.) cvs. Rongrien and See-Chompoo[J]. Postharvest Biology and Technology, 2008, 50(2-3):164-168.
[25] 刘琦琦,徐娟,王黎明,等.外源H2S对“尖脆”枣果实贮藏品质及抗氧化能力的影响[J].北方园艺,2018(22):135-142.
[26] 刘畅,徐玉娟,李升锋,等.龙眼果肉中多酚氧化酶和过氧化物酶性质研究[J].食品工业科技,2008,29(7):102-104.
[27] QIAN C L,HE Z P, ZHAO Y Y,et al. Maturity-dependent chilling tolerance regulated by the antioxidative capacity in postharvest cucumber (Cucumis sativus L.) fruit[J]. Journal of the Science of Food & Agriculture, 2013, 93(3):626-633.
[28] MITTLER R, VANDERAUWERA S, GOLLERY M, et al. Reactive oxygen gene network of plants[J]. Trends in Plant Science, 2004, 9(10):490-498.
[29] LUO Z, LI D, DU R, et al. Hydrogen sulfide alleviates chilling injury of banana fruit by enhanced antioxidant system and proline content[J]. Scientia Horticulturae, 2015, 183:144-151.
[30] LI D, LIMWACHIRANON J, LI L, et al. Involvement of energy metabolism to chilling tolerance induced by hydrogen sulfide in cold-stored banana fruit[J]. Food Chemistry, 2016, 208:272-278.
[31] HU L Y, HU S L, WU J, et al. Hydrogen sulfide prolongs postharvest shelf life of strawberry and plays an antioxidative role in fruits[J]. Journal of Agricultural and Food Chemistry, 2012, 60(35):8 684-8 693.
[32] XIA Y X, CHEN T, QIN G Z, et al. Synergistic action of antioxidative systems contributes to the alleviation of senescence in kiwifruit[J]. Postharvest Biology and Technology, 2016, 111:15-24.
[33] YANG S Y, SU X G, PRASAD K N, et al. Qxidation and peroxidation of postharvest banana fruit during softening [J].Pakistan Journal of Botany,2008,40(5):2 023-2 029.
[34] WU B, GUO Q, LI Q, et al. Impact of postharvest nitric oxide treatment on antioxidant enzymes and related genes in banana fruit in response to chilling tolerance[J]. Postharvest Biology and Technology, 2014, 92:157-163.
[35] LIU Y J, JIANG H F, ZHAO Z G, et al. Nitric oxide synthase like activity-dependent nitric oxide production protects against chilling-induced oxidative damage in Chorispora bungeana suspension cultured cells[J]. Plant Physiology & Biochemistry, 2010, 48(12):936-944.
[36] SHI H, YE T, CHAN Z, et al. Nitric oxide-activated hydrogen sulfide is essential for cadmium stress response in bermudagrass (Cynodon dactylon (L). Pers.)[J]. Plant Physiology and Biochemistry, 2014, 74:99-107.
[37] HE Y, HUANG B. Differential responses to heat stress in activities and isozymes of four antioxidant enzymes for two cultivars of Kentucky bluegrass contrasting in heat tolerance[J]. Journal of the American Society for Horticultural Science, 2010, 135(2):116-124.
[38] SONG L L, GAO H Y, CHEN H J, et al. Effect of short-term anoxic treatment on antioxidant ability and membrane integrity of postharvest kiwifruit during storage [J]. Food Chemistry, 2009, 114(4): 1 216-1 221.
[39] SHAN C J, ZHANG S L, LI D F, et al. Effects of exogenous hydrogen sulfide on the ascorbate and glutathione metabolism in wheat seedlings leaves under water stress[J]. Acta Physiologiae Plantarum, 2011, 33(6):2 533-2 540.
[40] SHAN C, DAI H, SUN Y. Hydrogen sulfide protects wheat seedlings against copper stress by regulating the ascorbate and glutathione metabolism in leaves[J]. Australian Journal of Crop Science, 2012, 6(2):248-254.
[41] HU K, WANG Q, HU L, et al. Hydrogen sulfide prolongs postharvest storage of fresh-cut pears (Pyrus pyrifolia) by alleviation of oxidative damage and inhibition of fungal growth[J]. PLoS ONE, 2014, 9(1):e85524.
[42] DIAO Q N, SONG Y J, SHI D M, et al. Nitric oxide induced by polyamines involves antioxidant systems against chilling stress in tomato (Lycopersicon esculentum Mill.) seedling[J]. Journal of Zhejiang University Science B, 2016, 17(12):916-930.
[43] LIANG Y, ZHENG P, LI S, et al. Nitrate reductase-dependent NO production is involved in H2S-induced nitrate stress tolerance in tomato via activation of antioxidant enzymes[J]. Entia Horticulturae, 2018, 229:207-214.
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